Passive techniques for long-term reactor cooling

ABSTRACT

In a pressurized water reactor (PWR), emergency core cooling (ECC) responds to depressurization due to a vessel penetration break at the top of the pressure vessel by draining water from a body of water through an injection line into the pressure vessel. A barrier operates concurrently with the ECC to suppress flow of liquid water from the pressure vessel out the vessel penetration break. The barrier may comprise one or more of: (1) an injection line extension passing through the central riser to drain water into the central riser; (2) openings in a lower portion of a central riser to shunt some upward flow from the central riser into a lower portion of the downcomer annulus; and (3) a surge line providing fluid communication between a pressurizer volume at the top of the pressure vessel and the remainder of the pressure vessel which directs water outboard toward the downcomer annulus.

This application claims the benefit of U.S. Provisional Application No.61/794,206 filed Mar. 15, 2013 and titled “PASSIVE TECHNIQUES FORLONG-TERM REACTOR COOLING”. U.S. Provisional Application No. 61/794,206filed Mar. 15, 2013 and titled “PASSIVE TECHNIQUES FOR LONG-TERM REACTORCOOLING” is hereby incorporated by reference in its entirety into thespecification of this application.

This invention was made with Government support under Contract No.DE-NE0000583 awarded by the Department of Energy. The Government hascertain rights in this invention.

BACKGROUND

The following relates to the nuclear power generation arts, nuclearreactor safety arts, nuclear reactor emergency core cooling (ECC) arts,and related arts.

In a loss of coolant accident (LOCA), the nuclear reactor core is to bekept immersed in water so as to provide for removal of decay heat and toprevent exposure of the fuel rods to air which can lead to chemicalreactions and release of airborne radioactivity. The system whichprovides this water injection is referred to as the emergency corecooling (ECC) system. In a typical arrangement, a refueling waterstorage tank (RWST) is located with the nuclear reactor insideradiological containment to provide water for use during reactorrefueling, and this RWST also serves as a water source for the ECCsystem. The RWST is located above the reactor core so that the passiveECC system can operate by gravity-driven water flow.

Water injected into the depressurized pressure vessel by the ECC systemis converted to steam by decay heat from the nuclear reactor core.Preferably, this steam is recaptured by condensing it into the RWST soas to form a closed-loop recirculating heat exchange system. Inpractice, some steam is lost from the break that caused the LOCA. Thislost steam condenses inside the surrounding radiological containment,thereby contributing to heat transfer from the reactor core although notin a recirculating fashion. In some embodiments, the water collects in acontainment sump, and a sump pump is provided to recirculate the waterback into the RWST. However, this approach is susceptible to failure ifthe diesel generators or other power source driving the sump pump fail,and moreover there is the potential to transfer contamination into theRWST that can interfere with operation of the ECC system.

BRIEF SUMMARY

In one disclosed aspect, an apparatus comprises: a pressurized waterreactor (PWR) comprising a pressure vessel containing a nuclear reactorcore comprising fissile material; a radiological containment structureinside of which the PWR is disposed; an emergency core cooling systemconfigured to respond to a vessel penetration break at the top of thepressure vessel that results in depressurization of the pressure vesselby draining water from a body of water through an injection line intothe pressure vessel; and a barrier configured to operate concurrentlywith the emergency core cooling system to suppress flow of liquid waterfrom the pressure vessel out the vessel penetration break at the top ofthe pressure vessel. The barrier may comprise one or more of: (1) anextension of the injection line disposed inside the pressure vessel andpassing through the central riser to drain water from the body of waterinto the central riser of the pressure vessel; (2) openings in a lowerportion of a central riser arranged to shunt a portion of the upwardflow in the central riser into a lower portion of the downcomer annulus;and (3) a surge line configured to provide fluid communication between apressurizer volume at the top of the pressure vessel and the remainderof the pressure vessel, the surge line configured to direct wateroutboard toward a downcomer annulus.

In another disclosed aspect, a method comprises operating a pressurizedwater reactor (PWR) comprising a pressure vessel containing a nuclearreactor core comprising fissile material, and responding to a vesselpenetration break at the top of the pressure vessel that results indepressurization of the pressure vessel by operations including:draining water from a body of water through an injection line into thepressure vessel; and during the draining, suppressing flow of liquidwater from the pressure vessel out the vessel penetration break. Thesuppressing may include generating a counterflow in the pressure vesselduring the draining in a direction opposite a flow of coolant water inthe pressure vessel during the operating, for example by injecting thewater from the body of water into the central riser. The suppressingadditionally or alternatively may comprise shunting a portion of theupward flow of coolant water in the central riser through holes in thecentral riser and into a lower portion of the downcomer annulus withoutthe shunted water reaching a top of the central riser. The suppressingadditionally or alternatively may comprise directing surge flow betweena pressurizer volume and the remainder volume of the pressure vesseloutboard toward a downcomer annulus.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention may take form in various components and arrangements ofcomponents, and in various process operations and arrangements ofprocess operations. The drawings are only for purposes of illustratingpreferred embodiments and are not to be construed as limiting theinvention. This disclosure includes the following drawings.

FIG. 1 shows a diagrammatic cutaway perspective view of an illustrativesmall modular reactor (SMR) disposed in a radiological containmentstructure along with a refueling water storage tank (RWST) with anemergency core cooling (ECC) system utilizing the RWST, and furtherincluding a diagrammatically indicated mechanism for suppressing loss ofliquid water through a LOCA break.

FIGS. 2-4 diagrammatically show illustrative embodiments of themechanism for suppressing loss of liquid water through the LOCA break.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

With reference to FIG. 1, a cutaway perspective view is shown of anillustrative small modular reactor (SMR) 10 and an illustrativerefueling water storage tank (RWST) 12 (typically, two or more RWSTs areprovided for redundancy). The SMR unit 10 is of the pressurized waterreactor (PWR) variety, and includes a pressure vessel 14 and one or moreintegral steam generators 16 disposed inside the pressure vessel 14(that is, the illustrative SMR 10 is an integral PWR 10). Alternatively,an external steam generator may be employed. The SMR 10 also includes anintegral pressurizer 18 defining an integral pressurizer volume 19 atthe top of the pressure vessel 14; alternatively, an externalpressurizer may be employed that is connected at the top of the SMR 10by suitable piping. The pressure vessel 14 contains a nuclear reactorcore 20 comprising fissile material such as ²³⁵U (typically in an alloy,composite, mixture, or other form) immersed in (primary) coolant water(more generally herein, simply “coolant” or “coolant water”). With thereactor core 20 immersed in coolant water, and when control rod drivemechanisms (CRDMs) 22 at least partially withdraw control rods made ofneutron-absorbing material, a nuclear chain reaction is initiated in thenuclear reactor core 20 which heats the (primary) coolant water. Theillustrative CRDMs 22 are internal CRDMs, in which the CRDM unitincluding its motor 22 m including both rotor and stator are disposedinside the pressure vessel 14, and guide frame supports 23 guide theportions of the control rods located above the core; in otherembodiments, external CRDM units may be employed. In the illustrativeintegral PWR 10, a separate water flow (secondary coolant) enters andexits the steam generators 16 via feedwater inlet 24 and steam outlets26, respectively. The secondary coolant flows through secondary coolantchannels of the steam generator or generators 16, and is converted tosteam by heat from the reactor core carried by the (primary) coolantwater. Alternatively, if an external steam generator is employed thenlarge-diameter closed-loop piping feeds (primary) coolant water from thepressure vessel to the external steam generator where heat from theprimary coolant converts secondary coolant flow in the external steamgenerator to steam. The pressure vessel 14 of the illustrative integralPWR 10 includes a lower portion 30 housing the nuclear reactor core 20and an upper portion 32 housing the steam generators 16, with amid-flange 34 connecting the upper and lower portions of the pressurevessel; however, the pressure vessel may be otherwise constructed orotherwise configured.

A primary coolant flow circuit F inside the pressure vessel 14 isdefined by a cylindrical central riser 36 extending upward above thereactor core 20 and a downcomer annulus 38 defined between the centralcylindrical riser 36 and the pressure vessel 14. The flow F may bedriven by natural circulation (i.e. by primary coolant heated by thereactor core 20 rising through the central cylindrical riser 36,discharging at the top and flowing downward through the downcomerannulus 38), or may be assisted or driven by reactor coolant pumps(RCPs), such as illustrative RCPs including RCP casings 40 containingimpellers driven by RCP motors 42. The RCPs may alternatively be locatedelsewhere along the primary coolant path, or omitted entirely in anatural circulation reactor. It is again noted that the illustrative SMR10 is merely an illustrative example, and the disclosed ECC techniquesare suitably employed with substantially any type of light water nuclearreactor.

With continuing reference to FIG. 1, a diagrammatic sectional view isshown of the SMR 10 disposed in a radiological containment structure 50(also referred to herein as “radiological containment” or simply“containment”) along with the refueling water storage tank (RWST) 12.While a single RWST 12 is illustrated, it is to be understood that twoor more RWSTs may be disposed inside containment to provide redundancyand/or to provide a larger total volume of water. The RWST 12 servesmultiple purposes. As the name implies, is provides water for use duringroutine refueling (that is, removal of spent fuel comprising the nuclearreactor core and its replacement with fresh fuel). The RWST 12 alsoserves as a water reserve for use during certain accident scenarios,such as a loss of heat sinking event in which the heat sinking via thesteam generators 16 or other heat sinking pathway is interrupted causingthe pressure and temperature in the reactor pressure vessel 14 to rise;or a loss of coolant accident (LOCA) in which a break occurs in a(relatively large-diameter) pipe or vessel penetration connected withthe pressure vessel 14.

FIG. 1 diagrammatically illustrates the response to a LOCA comprising abreak from which steam 52 (possibly in the form of a two-phasesteam/water mixture 52) escapes. In FIG. 1 such a LOCA isdiagrammatically indicated as originating in the proximity of theintegral pressurizer 18 at the top of the pressure vessel 14. In someembodiments the SMR 10 is designed to eliminate the possibility of aLOCA break occurring at an elevation equal to or lower than the top ofthe reactor core 20. This can be done by designing the pressure vessel14 with all large-diameter vessel penetrations located above the top ofthe reactor core 20 (e.g., the steam generator couplings 24, 26 are solocated in the embodiment of FIG. 1). As used herein, “large diameter”vessel penetrations are defined as vessel penetrations of diameter1.8-inch or larger. Additionally or alternatively, passive integralisolation valves may be employed for large-diameter vessel penetrations,so that any pipe breakage at the vessel penetration is immediately andpassively sealed by the integral isolation valve. For example, in thecase of a make-up line or other water input line, the passive integralisolation valve may be constructed as a check valve built into themounting flange (rather than in or connected by external piping that issusceptible to breakage) that operates passively to prevent outflow ofcoolant from the flange having the integral valve. In the case of aletdown line, the passive integral isolation valve can be constructedwith a spring bias that maintains the valve in the open position againstthe pressure of fluid flowing out via the letdown line, with the springbias chosen such that an increase in (differential) outward pressureabove a threshold value overcomes the spring bias to passively close thevalve. Again, the integral isolation valve is preferably built into themounting flange.

With such measures, it can be ensured that any LOCA break occurs at anelevation well above the top of the reactor core 20. In the illustrativepressure vessel 14, the only large-diameter vessel penetrationssusceptible to a break constituting a LOCA are located at the integralpressurizer 18 at the top of the pressure vessel 14. In such a LOCA, thesteam/water 52 that escapes from the integral pressurizer 18 of thepressure vessel 14 is contained by the radiological containment 50, andthe released energy is ejected to an ultimate heat sink (UHS) 54 via asuitable transfer mechanism. In illustrative FIG. 1, this heat transferis achieved (at least in part) by direct thermal contact between the UHS54 which comprises a large body of water located on top of and inthermal contact with the top of the containment 50. Additionally, apassive emergency core cooling (ECC) is activated, which depressurizesthe reactor 10 using valves connected to the pressurizer 18 (in theillustrative example of FIG. 1, or elsewhere in other reactor designs)to vent the pressure vessel 14 to the RWST 12. This operation isdiagrammatically indicated by steam path 60 carrying steam (or two-phasesteam/water mixture) from the pressurizer 18 to be re-condensed in theRWST 12. Any excess pressure in the RWST 12 resulting from the ventingof the pressure vessel to the RWST escapes via a steam vent 62 from theRWST. While depressurizing the reactor, water is initially injected intothe reactor vessel from two (for redundancy, or more than two forfurther redundancy) nitrogen pressurized intermediate pressure injectiontanks (IPIT, of which one illustrative IPIT 64 is shown in FIG. 1) toassure the reactor core 20 remains immersed in coolant water during thedepressurization. The water in the IPIT 64 optionally includes boron oranother neutron poison to facilitate rapid shutdown of the nuclear chainreaction. Once the reactor 10 is depressurized, water in the RWST 12 (orRWSTs, if two or more redundant RWST units are provided insidecontainment) drains into the reactor vessel 14 via an injection line 66running from the RWST 12 to the reactor pressure vessel, thus refillingthe vessel 14. (Note that in illustrative FIG. 1, a downstream portionof the injection line 66 also provides the input path for water from theIPIT 64, in which case suitable valving is provided to valve off theIPIT 64 after initial depressurization is complete. The valving isoptionally passive, e.g. automatically closing when the pressure in thepressure vessel 14 falls below a setpoint. It is also contemplated toconnect the IPIT with the reactor pressure vessel via a separate linefrom the injection line 66.) The water in the RWST(s) 12 provideslong-term cooling for the reactor core 20.

The RWST 12 is a large body of water conveniently located inside theradiological containment structure 50 and hence is an attractive body ofwater for use by the ECC system; however, it is alternativelycontemplated to connect the injection line 66 to another suitably largebody of water that is located at an elevated position respective to thereactor core 20 so as to be drained into the pressure vessel 14 so as toprovide emergency core cooling (ECC).

During the depressurization, it is expected that substantial primarycoolant in the form of steam will exit the pressure vessel 14 via thebreak that caused the LOCA. After startup of the ECC system, it isexpected that steam will continue to exit the pressure vessel 14 via thebreak, albeit at a lower mass flow rate than during the initialdepressurization. In some embodiments the volume capacity of the RWST(s)12 is designed to be sufficient to remove decay heat for a design timeinterval, e.g. 72 hours in some embodiments, or 14 days in otherembodiments, without the need to recirculate water from a containmentsump using sump pumps. This avoids the potential for transferringcontaminants from the sump into the RWST.

Because the ECC system relies upon gravity feed of water from the RWST12 into the pressure vessel 14, it is necessary for the water level inthe RWST 12 to be higher than the water level in the pressure vessel 14in order for the ECC to operate. In some embodiments, the initial waterlevel in the RWST 12 is higher than the top of the pressure vessel 14—insuch embodiments, it is expected that the water level in the reactorvessel 14 will rise to the top of the pressurizer 18 and liquid waterwill flow out through the LOCA break. However, once the water level inthe RWST 12 drops below the top of the pressurizer 18, it might beexpected that the flow out of the break would transition from mostlywater to essentially all steam. This transition allows efficientutilization of the RWST water inventory. Since the heat capacity of thewater then includes the latent heat for converting the water to steam.

However, RELAP (Reactor Excursion and Leak Analysis Program) analysis oflong-term cooling indicates that this is not necessarily the case;rather, a two-phase steam/water mixture with substantial water contentcontinues to leave the LOCA break even after the water level in the RWST12 has drained below the level of the LOCA break. Without being limitedto any particular theory of operation, it is believed that this effectis caused as follows. Decay heat from the reactor core 20 generatessteam that reduces the density of the water above the reactor core 20.This effect prevents an equilibrium from being established between thewater/steam column in the reactor vessel 14 and the water column in theRWST 12. The higher RWST driving head therefore continues to force waterout of the break.

The magnitude of the problem is illustrated by a simple calculation,performed for a nuclear island design substantially similar to thatshown in FIG. 1, in which the RWST (or plurality of RWSTs) has acapacity of about 350,000 gallons, the initial water level in the RWSTis at an elevation of 95 feet, and the LOCA break is at a point 10 feetlower in elevation, i.e. at 85 feet. At 120° F., the water in the RWSThas a density of 61.7 lb/ft³ (pounds/cubit foot). At 15 psia, saturatedwater has a density of 59.8 lb/ft³ and steam has a density of 0.038lb/ft³. If the ECC inlet to the vessel (that is, the inlet of theinjection line 66 to the pressure vessel 14 in illustrative FIG. 1) hasan elevation of 31 feet and an average quality of 1% (that is, the waterflowing in from the RWST is almost purely water with little or no steamcontent), then the density inside the reactor would be 3.58 lb/ft³. Inthis case, the water level in the RWST would need to drop to anelevation of about 34 ft (which is 7 feet below the bottom of the RWSTin some contemplated embodiments) in order to reach an equilibriumstatic head.

To compensate for this effect it is disclosed herein that the totalquality in the central riser 36 (or other upward flow path of thecirculating primary coolant) is reduced, or additional pressure drop isincorporated into the ECC injection system. Toward this end, a barriermechanism, diagrammatically indicated in FIG. 1, is implemented tosuppress the flow of liquid water in the central riser 36 (or otherupward flow path of the circulating primary coolant) from passing upwardto the LOCA break. The barrier may take the various forms, as describedin the following. In some embodiments (described herein with referenceto FIG. 2), the barrier comprises a modification of the pathwaysconnecting the volume contained by the central riser 36 with theinternal pressurizer volume 19. This approach forms the barrier as adirect physical barrier, i.e. a baffle or tortuous path that limits theflow of liquid water from the central riser 36 into the internalpressurizer 18. In some embodiments (described herein with reference toFIG. 3), the barrier comprises modifying the ECC system so that itinjects water from the RWST 12 into the central riser 36 in a mannerthat tends to drive circulation in a direction opposing the primarycoolant flow circuit F inside the pressure vessel 14. This forms thebarrier indirectly, by slowing or even reversing the velocity of theprimary coolant flow circuit F so as to limit the flow of liquid waterfrom the central riser 36 into the internal pressurizer 18. In someembodiments (described herein with reference to FIG. 4), the barriercomprises providing bypass valves that divert a portion of the upwardflow leg of the primary coolant flow circuit F from the central riser 36into the downcomer annulus 38. This again forms the barrier indirectly,by reducing the volume of upward flow in the central riser 36 so as tolimit the flow of liquid water from the central riser 36 into theinternal pressurizer 18. It will be appreciated that these mechanismsare not mutually exclusive, and the barrier may comprise a combinationof two or more of these mechanisms or variants thereof.

In general, the amount of steam generated in the reactor vessel 14 aftera LOCA is determined by the core decay heat. This cannot be altered bythe designer without changing the power level of the plant. However, thequality in the riser 36 can be improved by increasing the flow of waterwithin the riser, by constructing the pressure vessel 14 to beconfigured to entrain water with the steam. Toward this end, a flow pathis provided with the barrier so as to separate the steam and water atthe top of the reactor vessel 14 allowing the water to flow to thebottom of the pressure vessel 14 where it can be entrained with steam inthe core again.

The high quality natural circulation path should interface with thepressurizer 18 in a way that allows the excess water to be separated anddirected back to the bottom of the pressure vessel 14. However, this isdifficult to achieve in the context of an integral pressurizer, becauseflow paths are designed to permit relatively free fluid communicationbetween the volume contained in the central riser 36 and the volume 19of the integral pressurizer 18.

With reference to FIG. 2, and in particular the inset of FIG. 2, whenthe RWST 12 has sufficient driving head to fill the reactor vessel 14,two-phase flow rises and enters the pressurizer 18 through stand pipes80 that extend through a pump support plate 82. (More generally, thestand pipes 80 pass through a plate separating the pressurizer space 19from the remainder of the pressure vessel volume. Note that in the insetof FIG. 2 the illustrative RCPs 40, 42 are removed for clarity leavingmounting openings 84 in their place in the pump support plate 82. Moregenerally, the RCPs may be located elsewhere, or may be omitted entirelyin a natural circulation reactor.) The surge pipes 80 provide steamventing into the pressurizer space 19 during reactor depressurization.During normal operation, surge lines 86 are provided via which waterpasses, in a constricted manner e.g. by baffles or the like, to allowpressure in the pressurizer 18 and remainder of the pressure vessel 14to reach an equilibrium. During normal operation, pressure controlelements 88, e.g. resistive heaters, spargers, or the like, are operableto raise or lower the pressure in the pressurizer volume 19, with thesurge lines 86 allowing these changes to transfer to the loweroperational portion of the pressure vessel 14.

During depressurization, however, the surge lines 86 allow watercollected in the pressurizer to drain out through the surge lines 86.This flow is directed into the rising two-phase steam/water flow risingup in the central riser 36. This prohibits a natural flow of the water,increasing the average quality within the riser.

In the embodiment of the barrier of FIG. 2, the pressurizer surge line86 is modified to discharge along paths 90 that direct the water throughthe reactor coolant pumps and then down the tubes of the steamgenerators 16. (More generally, the modified surge lines 90 direct wateroutboard toward the downcomer annulus, and are also suitably employed inembodiments that do not employ RCPs or that locate RCPs elsewhere alongthe primary coolant flow circuit.) These modified paths 90 can be usedduring normal reactor operation as the surge lines, or can be opened bypassive valves in response to an overpressure condition. In anotheralternative embodiment, the paths 90 are omitted and instead passiveoverpressure shutoff valves are installed on the surge lines 86 to closethese lines off during ECC operation so that only the stand pipes 80provide steam transport pathways into the pressurizer volume 90.

With reference to FIG. 3, in another embodiment of the barrier, theinlet of the injection line 66 to the pressure vessel 14, whichconventionally feeds into the downcomer annulus 38, is modified byadding an extension pipe 100 so as to feed into the central riser 36.Optionally, the extension pipe 100 has a downwardly oriented outletspigot 102 so as to direct the injected coolant from the RWST 12downward. As diagrammatically indicated in FIG. 3, this tends to producea coolant circulation flow -F oriented opposite to the direction fromthe primary coolant flow circuit F inside the pressure vessel 14 that isdriven by the decay heat from the reactor core 20. In some embodiments,the magnitude of the counterflow -F is sufficient to actually reversethe direction of circulation in the pressure vessel 14, while in otherembodiments the magnitude of the counterflow -F is less than that of theflow F, but is sufficient to slow the velocity of the flow F. Thecounterflow -F aligns with the discharge of water through thepressurizer, and thereby has the effect of reducing the flow of waterinto the pressurizer volume 19 driven by the upward current of the flowF in the central riser 36. The counterflow -F can be interrupted whenECC flow is sufficiently low, or if some heat removal is availablethrough a remedial operational mode of the steam generator (inembodiments that include the internal steam generator 16).

With reference to FIG. 4, in another embodiment of the barrier, acirculation pattern 108 is created using openings 110 in the core barrel(or other lower portion of the vessel central riser 36) so that aportion of the upward flow in the central riser 36 is shunted into thelower portion of the downcomer annulus 38 without passing upward intoproximity with the pressurizer 18. The openings 110 can be holes, holeswith flow diodes (i.e. check valves) or passively opened bypass valvesto minimize normal bypass flow. This allows natural circulation flow 108in the lower vessel. The flow 108 can be either in the normal direction(as illustrated) or in the reverse direction.

It is to be appreciated that the disclosed mechanisms for implementingthe barrier 70 described with reference to FIGS. 2-4 are merelyillustrative, and may be combined in various ways. As anotherillustrative example, if the RCPs are located in a lower portion of thepressure vessel such that they are submerged during the ECC operation,and if electrical drive power is available, then it is contemplated toimplement the barrier at least in part by operating the RCPs inretrograde so as to provide the counterflow -F (see FIG. 3) in an activefashion. (Although such operation may be relatively inefficient sincethe impeller blades are not designed for retrograde operation, the RCPsare nonetheless expected to be capable of generating counterflow -Fsufficient to usefully reduce flow of water out the LOCA break.) Thedisclosed barrier is effective for a pressurized water reactor (PWR) inthe case of a LOCA break occurring at the top of the pressure vessel,e.g. in a vessel penetration into an integral pressurizer (asillustrated in FIGS. 1-4) or at piping between the top of the pressurevessel and an external pressurizer or at piping connecting at the top ofsuch an externally pressurized vessel (variants not illustrated). Asused herein, phraseology such as “top of the pressure vessel” isintended to encompass any break in a vessel penetration into theintegral pressurizer 18 that is large enough to constitute a LOCA (thatis, any break in a pipe of diameter greater than 1.8-inch). In the caseof an externally pressurized vessel (that is, a pressure vessel that ispressurized using an external pressurizer connected via piping), “top ofthe pressure vessel” is intended to encompass any break large enough toconstitute a LOCA in a vessel penetration at an elevation high enough tobe located above the primary coolant circuit in the pressure vessel.Still further, while integral PWR systems in which steam generators 16are disposed inside the pressure vessel 14 are illustrated, it iscontemplated to employ the disclosed embodiments of the barrier in PWRsystems that utilize external steam generators.

The preferred embodiments have been illustrated and described.Obviously, modifications and alterations will occur to others uponreading and understanding the preceding detailed description. It isintended that the invention be construed as including all suchmodifications and alterations insofar as they come within the scope ofthe appended claims or the equivalents thereof.

We claim:
 1. An apparatus comprising: a pressurized water reactor (PWR)comprising a pressure vessel containing a nuclear reactor corecomprising fissile material; a central riser disposed inside thepressure vessel and defining a coolant circulation path in which coolantwater heated by the nuclear reactor core flows upward inside the centralriser, exits a top opening of the central riser, and flows downward in adowncomer annulus defined between the central riser and the pressurevessel to return to the nuclear reactor core; a radiological containmentstructure inside of which the PWR is disposed; an emergency core coolingsystem configured to drain water from a body of water through aninjection line into the pressure vessel in response to a vesselpenetration break at the top of the pressure vessel that depressurizesthe pressure vessel; and an extension of the injection line disposedinside the pressure vessel and passing through the central riser, theextension configured to operate concurrently with the emergency corecooling system to suppress flow of liquid water from the pressure vesselout the vessel penetration break at the top of the pressure vessel. 2.The apparatus of claim 1 wherein the extension of the injection lineincludes a downwardly oriented outlet spigot disposed inside the centralriser.
 3. The apparatus of claim 1 wherein the body of water comprises arefueling water storage tank (RWST) disposed with the PWR in theradiological containment.
 4. The apparatus of claim 3 wherein theemergency core cooling system further includes: a pressurized waterinjection tank configured to inject pressurized water into the pressurevessel during depressurization of the pressure vessel; wherein theinjection line is configured to drain water from the RWST into thepressure vessel after the depressurization of the pressure vessel. 5.The apparatus of claim 1 wherein the PWR further comprises an integralpressurizer defining a pressurizer volume at the top of the pressurevessel, the integral pressurizer including pressure control elementsoperable to control pressure in the pressurizer volume.
 6. The apparatusof claim 1 further comprising: openings in a lower portion of thecentral riser arranged to shunt a portion of the upward flow in thecentral riser into a lower portion of the downcomer annulus.
 7. Theapparatus of claim 1 wherein: an integral pressurizer defining apressurizer volume at the top of the pressure vessel and includingpressure control elements operable to control pressure in thepressurizer volume; and a surge line configured to provide fluidcommunication between the pressurizer volume at the top of the pressurevessel and the remainder of the pressure vessel, the surge lineconfigured to direct water outboard toward the downcomer annulus.